Efficient Hydrogen Production from Methanol Using a Single-Site Pt_1/CeO_2 Catalyst

Chen Lu-Ning; Hou Kai-Peng; Liu Yi-Sheng; Qi Zhi-Yuan; Zheng Qi; Lu Yi-Hsien; Chen Jia-Yu; Chen Jeng-Lung; Pao Chih-Wen; Wang Shuo-Bo; Li Yao-Bin; Xie Shao-Hua; Liu Fu-Dong; Prendergast David; Klebanoff Leonard E.; Stavila Vitalie; Allendorf Mark D.; Guo Jinghua; Zheng Lan-Sun; Su Ji; Somorjai Gabor A.

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Efficient Hydrogen Production from Methanol Using a Single-Site Pt_1/CeO_2 Catalyst

机译：使用单站点Pt_1 / CeO_2催化剂从甲醇高效生产氢

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Hydrogen is regarded as an attractive alternative energy carrier due to its high gravimetric energy density and only water production upon combustion. However, due to its low volumetric energy density, there are still some challenges in practical hydrogen storage and transportation. In the past decade, using chemical bonds of liquid organic molecules as hydrogen carriers to generate hydrogen in situ provided a feasible method to potentially solve this problem. Research efforts on liquid organic hydrogen carriers (LOHCs) seek practical carrier systems and advanced catalytic materials that have the potential to reduce costs, increase reaction rate, and provide a more efficient catalytic hydrogen generation/storage process. In this work, we used methanol as a hydrogen carrier to release hydrogen in situ with the single-site Pt-1/CeO2 catalyst. Moreover, in this reaction, compared with traditional nanoparticle catalysts, the single site catalyst displays excellent hydrogen generation efficiency, 40 times higher than 2.5 nm Pt/CeO2 sample, and 800 times higher compared to 7.0 nm Pt/CeO2 sample. This in-depth study highlights the benefits of single-site catalysts and paves the way for further rational design of highly efficient catalysts for sustainable energy storage applications.

机译：氢气由于具有很高的重量能量密度并且仅在燃烧时产生水，因此被视为有吸引力的替代能源载体。然而，由于其低的体积能量密度，在实际的氢存储和运输中仍然存在一些挑战。在过去的十年中，使用液态有机分子的化学键作为氢载体原位产生氢提供了一种可行的方法来潜在地解决该问题。液态有机氢载体（LOHC）的研究工作寻求实用的载体系统和先进的催化材料，它们有可能降低成本，提高反应速率并提供更有效的催化氢产生/存储过程。在这项工作中，我们使用甲醇作为氢载体与单中心Pt-1 / CeO2催化剂原位释放氢。此外，在该反应中，与传统的纳米颗粒催化剂相比，单中心催化剂显示出优异的氢生成效率，比2.5 nm Pt / CeO2样品高40倍，比7.0 nm Pt / CeO2样品高800倍。这项深入的研究凸显了单中心催化剂的优势，并为进一步合理设计高效催化剂以实现可持续储能铺平了道路。

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来源
《Journal of the American Chemical Society》 |2019年第45期|17995-17999|共5页
作者
Chen Lu-Ning; Hou Kai-Peng; Liu Yi-Sheng; Qi Zhi-Yuan; Zheng Qi; Lu Yi-Hsien; Chen Jia-Yu; Chen Jeng-Lung; Pao Chih-Wen; Wang Shuo-Bo; Li Yao-Bin; Xie Shao-Hua; Liu Fu-Dong; Prendergast David; Klebanoff Leonard E.; Stavila Vitalie; Allendorf Mark D.; Guo Jinghua; Zheng Lan-Sun; Su Ji; Somorjai Gabor A.;
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Lawrence Berkeley Natl Lab Mat Sci Div Berkeley CA 94720 USA|Xiamen Univ Coll Chem & Chem Engn Collaborat Innovat Ctr Chem Energy Mat State Key Lab Phys Chem Solid Surfaces Xiamen 361005 Fujian Peoples R China|Xiamen Univ Coll Chem & Chem Engn Dept Chem Xiamen 361005 Fujian Peoples R China;

Lawrence Berkeley Natl Lab Mat Sci Div Berkeley CA 94720 USA|Univ Calif Berkeley Dept Chem Berkeley CA 94720 USA;

Lawrence Berkeley Natl Lab Adv Light Source Berkeley CA 94720 USA;

Lawrence Berkeley Natl Lab Mat Sci Div Berkeley CA 94720 USA;

Xiamen Univ Coll Chem & Chem Engn Collaborat Innovat Ctr Chem Energy Mat State Key Lab Phys Chem Solid Surfaces Xiamen 361005 Fujian Peoples R China|Xiamen Univ Coll Chem & Chem Engn Dept Chem Xiamen 361005 Fujian Peoples R China;

Natl Synchrotron Radiat Res Ctr Sci Based Ind Pk Hsinchu 30076 Taiwan;

Chinese Acad Sci Inst Urban Environm Xiamen 361021 Fujian Peoples R China;

Univ Cent Florida Nanosci Technol Ctr NSTC Catalysis Cluster Renewable Energy & Chem Transfo Dept Civil Environm & Construct Engn Orlando FL 32916 USA;

Lawrence Berkeley Natl Lab Mat Sci Div Mol Foundry Berkeley CA 94720 USA;

Sandia Natl Labs Livermore CA 94551 USA;

Lawrence Berkeley Natl Lab Mat Sci Div Berkeley CA 94720 USA|Lawrence Berkeley Natl Lab Mat Sci Div Mol Foundry Berkeley CA 94720 USA;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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入库时间 2022-08-18 05:13:24

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1. Mechanism of Methanol Decomposition over Single-Site Pt_1/CeO_2 Catalyst: A DRIFTS Study [J] . Zhiyuan Qi, Liming Chen, Shuchen Zhang, Journal of the American Chemical Society . 2021,第1期

机译：单点甲醇分解机制PT_1 / CEO_2催化剂：漂移研究
2. Insights into the Mechanism of Methanol Steam Reforming Tandem Reaction over CeO_2 Supported Single-Site Catalysts [J] . Luning Chen, Zhiyuan Qi, Xinxing Peng, Journal of the American Chemical Society . 2021,第31期

机译：CEO_2支持的单次催化剂中甲醇蒸汽重整串联反应的机理洞察
3. Morphology effect of ceria on the performance of CuO/CeO_2 catalysts for hydrogen production by methanol steam reforming [J] . Yang Shuqian, Zhou Feng, Liu Yujuan, International journal of hydrogen energy . 2019,第14期

机译：二氧化铈对甲醇水蒸气重整制氢用CuO / CeO_2催化剂性能的形态学影响
4. Catalyzing Sustainable Fuel Production: Development of Cu-based Catalysts for the Hydrogenation of CO2 to Methanol [C] . Julia Schumann, Nygil Thomas, Andrey Tarasov National Meeting Exhibition . 2013

机译：催化可持续燃料生产：开发Cu基催化剂的CO 2氢化至甲醇
5. Mechanistic studies of hydrogen production from methanol on palladium zinc catalysts. [D] . Jeroro, Eseoghene. 2010

机译：钯锌催化剂上甲醇制氢的机理研究。
6. Exploring the ternary interactions in Cu–ZnO–ZrO2 catalysts for efficient CO2 hydrogenation to methanol [O] . Yuhao Wang, Shyam Kattel, Wengui Gao, -1

机译：探索Cu-ZnO-ZrO2催化剂中的三元相互作用以有效地将CO2加氢成甲醇
7. Efficient Hydrogen Production from Methanol Using a Single-Site Pt1/CeO2 Catalyst [O] . Lu-Ning Chen, Kai-Peng Hou, Yi-Sheng Liu, 2019

机译：使用单点PT1 / CEO2催化剂的甲醇的高效氢生产

Efficient Hydrogen Production from Methanol Using a Single-Site Pt_1/CeO_2 Catalyst

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